Charge transfer device and a driving method thereof and a driving method for solid-state image sensing device

ABSTRACT

A driving method for a solid-state image sensing device having a plurality of sensor portions being disposed two-dimensionally in a horizontal and a vertical directions, and a vertical charge transfer portion being disposed between said plurality of sensor portions and being provided with transfer electrodes of a plurality of systems disposed along its disposed direction, including the steps of; selectively applying high level driving pulses to the transfer electrodes of said plurality of systems in respective sectional periods in a vertical transfer period, and transferring the signal charges read out from said plurality of sensor portions in the vertical direction, wherein a sectional period in a vertical transfer period, in which the number of systems of the transfer electrodes to be applied with high level driving pulses becomes minimum is set longer than that of the other sectional periods. It is thus made possible to increase the handling charge quantity in the vertical charge transfer portion without changing time for transfer in the vertical transfer period.

RELATED APPLICATION DATA

The present application claims priority to Japanese Application No. P10-156944 filed Jun. 5, 1998, which application is incorporated herein by reference to the extent permitted by law.

BACKGROUND OF THE INVENTION

The present invention relates to a charge transfer device, such as a CCD and a driving method thereof, and a driving method for a solid-state image sensing device, in particular, it relates to a driving method for CCD solid-state image sensing devices of an IT (Inter-line Transfer) type.

In general, in a CCD solid-state image sensing device of the IT type, when signal charges are transferred, for example, by a vertical charge transfer portion (vertical shift register) having transfer electrodes of four systems, the transfer of signal charges for one line is performed in a horizontal blanking interval, and normally it is performed in a vertical transfer period being composed of eight sectional periods. In respective sectional periods, each one of four transfer electrodes is selectively applied with a high level driving pulse to control a depth of a potential well which is formed under each one of transfer the electrodes of respective systems, and the transfer of signal charges in a vertical direction is realized with the moves of signal charges described in the above. In a case where a read-out method in the interlaced scanning is changed to the read-out method in which all pixels are independently read out, or in a case where a constitution of a CCD solid-state sensing device responds to an electronic zoom lens or correction of blur caused by an unintentional hand move, it is needed to perform the charge transfer in the vertical charge transfer portion at a higher speed than usual.

However, when the transfer speed in the vertical charge transfer portion is made faster, with an increase in the transfer speed, the period of time for accumulating the charges in the vertical charge transfer portion is made shorter. Then the quantity of charges handled in the vertical charge transfer portion is decreased, and there is a fear that the transfer efficiency is lowered. In particular, for a CCD area sensor, there is a tendency that an increase in the number of pixels is demanded to realize high quality images in both a moving picture and a still picture. It is therefore necessary to take measures to such demands as the independent read-out of all pixels, or the improvement in techniques for an electronic zoom lens or correction of blur caused by an unintentional hand move, following to the upward tendency of requiring the increase in the number of pixels. Therefore, it looks inevitable that the transfer speed in the vertical charge transfer portion will continue to go up, so that it is desired to find an effective measure to suppress the decrease in the handling charge quantity in the vertical charge transfer portion.

SUMMARY OF THE INVENTION

The object of the present invention is to solve the aforementioned problems by providing a charge transfer device and a driving method thereof and a driving method for a solid-state image sensing device, more particularly, by providing a driving method for a solid-state image sensing device being able to suppress the decrease in the handling quantity of electric charges to the utmost when transferring signal charges at a high speed in the vertical charge transfer portion.

In order to achieve the object described in the above, according to an aspect of the present invention, there is provided A driving method for a solid-state image sensing device having a plurality of sensor portions being disposed two-dimensionally in a horizontal and a vertical directions, and a vertical charge transfer portion being disposed between the plurality of sensor portions and being provided with transfer electrodes of a plurality of systems disposed along its disposed direction, including the steps of; selectively applying high level driving pulses to the transfer electrodes of the plurality of systems in respective sectional periods in a vertical transfer period, and transferring the signal charges read out from the plurality of sensor portions in the vertical direction, wherein a sectional period in a vertical transfer period, in which the number of systems of the transfer electrodes to be applied with high level driving pulses becomes minimum is set longer than that of the other sectional periods.

According to another aspect of the present invention, there is provided a driving method for a charge transfer device having a charge transfer portion being formed of transfer electrodes of a plurality of systems disposed in the charge transfer direction, comprising the steps of; selectively applying a high level driving pulse to transfer electrodes of the plurality of systems in respective sectional periods in a transfer period, and transferring signal charges in a charge transfer portion, wherein a sectional period in the transfer period, in which the number of systems of the transfer electrodes to be applied with high level driving pulses becomes minimum are set longer than that of the other sectional periods.

According to a further aspect of the present invention, there is provided a charge transfer device having a charge transfer portion being formed of transfer electrodes of a plurality of systems disposed in the charge transfer direction; wherein high level driving pulses are applied to the transfer electrodes of the plurality of systems in respective sectional periods in a vertical transfer period, signal charges in a charge transfer portion are transferred, and a sectional period in a vertical transfer period, in which the number of systems of the transfer electrodes to be applied with high level driving pulses becomes minimum is set longer than that of the other sectional periods.

As described in the above, according to the present invention, it is made possible to increase the handling charge quantity in the vertical charge transfer portion without changing time for transfer in the vertical transfer period, so that in a case where signal charges are transferred at a high speed in the vertical charge transfer portion, for example, in a case of response to the read-out of all pixels being output independently, to the improvement of techniques in an electronic zoom lens or the correction of blur caused by an unintentional hand move, or to an increase in the number of stages in the vertical transfer, it is made possible to suppress the decrease in the handling charge quantity to the utmost.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view showing the constitution of a CCD area sensor of an IT type and its driving system;

FIG. 2 shows a timing chart during a vertical transfer in the case of 4-phase drive which is a subject of comparison with the present invention;

FIG. 3 shows a conceptual figure illustrating the transfer of signal charges during a vertical transfer in the case of 4-phase drive;

FIG. 4 shows a figure illustrating a correlation between a handling charge quantity and a transfer speed in the vertical charge transfer portion;

FIG. 5 shows a timing chart during a vertical transfer in the case of 4-phase drive shown in an embodiment according to the method in the present invention;

FIG. 6 shows an illustrative drawing for explaining the suppression effect for the decrease in the handling charge quantity according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

An explanation of embodiments of the present invention will be given in detail with reference to the drawings as follows.

FIG. 1 shows a schematic view illustrating the constitution of a CCD area sensor of an IT type and its driving system. In the figure, a sensor portion 1 is formed of namely, photodiodes being disposed two-dimensionally in a horizontal and a vertical directions. Each sensor portion 1 converts the incident light supplied thereto to signal charges having the quantity corresponding to the light quantity and accumulates them. Plural bars of vertical charge transfer portions 2 are disposed in the vertical direction between respective sensor portions 1. Each vertical transfer portion 2 is formed of a CCD (Charge Coupled Device), and the transfer electrodes of four systems are disposed along its disposed direction. These vertical charge transfer portions 2 are driven by vertical driving pulses of 4-phase from φV1 through φV4, supplied from a driving circuit 3, and in a part of the vertical blanking interval, it transfers the signal charges read out from respective sensor portions 1 through the read-out gate portion 4.

Further on an end side of respective vertical charge transfer portions 2, there is provided a horizontal charge transfer portion 5 in the orthogonal direction to the above, that is, in the horizontal direction thereof. The horizontal charge transfer portion 5 is driven by horizontal driving pulses φH1 and φH2 of 2-phase supplied from the driving circuit 3, for transferring the signal charges supplied from the vertical charge transfer portions 2 in the horizontal direction for a specific period of time in a horizontal scanning interval, for example, during a horizontal blanking interval. On the output side of the horizontal charge transfer portion 5 (that is, the charge transferring direction) there is provided a charge detection portion 6 formed of an FDA (Floating Diffusion Amplifier), for example, for detecting signal charges transferred in the horizontal direction and converting them into signal voltages.

Next, in FIG. 2, the timing chart during a vertical transfer in the case of 4-phase drive is shown, and in FIG. 3, the transfer image of signal charges corresponding to the above as a subject of comparison with the driving method of a solid-state image sensing device according to the present invention. In this place, a case where it is assumed that respective vertical driving pulses of 4-phase, φV1 to φV4 may take two values, a high level (H) or a low level (L), and the transfer of signal charges for one line is performed in a vertical transfer period being divided into eight sections, from t1 through t8, will be explained in citing as an example. In FIG. 3, it is assumed that the vertical driving pulses φV1, φV2, φV3 and φV4 are applied by the driving circuit 3 to the corresponding transfer electrodes φ1, φ2, φ3 and φ4 of 4 systems in the vertical charge transfer portion 2.

In the sectional period t0, before the vertical transfer is started, since the φV1 and the φV2 are kept in a high level, deep potential wells are formed under the transfer electrodes φ1 and φ2, allowing signal charges to be accumulated in these wells, and in this state, a vertical transfer period (from t1 through t8) is started.

In the sectional period t1, when φV3 is turned to a high level, deep potential wells are formed spreading over the transfer electrodes φ1, φ2 and φ3, and signal charges are accumulated under these transfer electrodes φ1, φ2 and φ3.

Next, in the sectional period t2, when the φV1 is turned to a low level, the potential well under the transfer electrode φ1 becomes shallow, so that signal charges are accumulated under the transfer electrodes φ2 and φ3.

In the next step, in the sectional period t3, when the φV4 is turned to a high level, deep potential wells are formed spreading over the transfer electrodes φ2, φ3 and φ4, so that signal charges are accumulated under these transfer electrodes φ2, φ3 and φ4.

Following to the sectional period t3, in the sectional period t4, when the φV2 is turned to a low level, the potential well under the transfer electrode φ2 becomes shallow, so that signal charges are accumulated under the transfer electrodes φ3 and φ4.

In the next step, in the sectional period t5, when the φV1 is turned to a high level, deep potential wells are formed spreading over the transfer electrodes φ3, φ4 and φ1, so that signal charges are accumulated under these transfer electrodes φ3, φ4 and φ1.

In the next step, in the sectional period t6, when φV3 is turned to a low level, the potential well under the transfer electrode φ3 becomes shallow, so that signal charges are accumulated under the transfer electrodes φ4 and φ1.

Incidentally, in the sectional period t7, when the φV2 is turned to a high level, deep potential wells are formed spreading over the transfer electrodes φ4, φ1 and φ2, so that signal charges are accumulated under these transfer electrodes φ4, φ1 and φ2.

In the last step, in the sectional period t8, when the φV4 is turned to a low level, the potential well under the transfer electrode φ4 becomes shallow, so that signal charges are accumulated under the transfer electrodes φ1 and φ2.

After taking above steps, the signal charges for one line in the vertical charge transfer portion 2 are transferred in a vertical direction.

In order to raise the transfer speed in the vertical charge transfer portion 2, it is necessary to shorten the transfer time T, the total of the above-mentioned eight sectional periods in a vertical transfer period. In such a case, in the driving method shown in FIG. 2, in each sectional period from t1 through t8 in a vertical transfer period, the transfer time per sectional period is made equal, so that when the transfer time for one line is shortened, naturally the sectional transfer period is also shortened.

At the same time, there is a tendency that the handling charge quantity in the vertical charge transfer portion 2 decreases with the shortening of the transfer time per sectional period.

FIG. 4 shows a figure illustrating a correlation between the handling charge quantity and the transfer speed (Hereinafter it can be referred to as Vφ speed). In the figure, a period of a certain reference clock pulse is put as 1-bit and the transfer speed is expressed with the number of bits in a sectional period, and when the number of bits is smaller (closer to zero), a faster transfer speed is expressed. From the figure, one will be able to perceive that faster is the transfer speed (shorter the transfer time per sectional period) smaller becomes the handling charge quantity.

When the handling charge quantity in the vertical charge transfer portion 2 decreases, even if a lot of signal charges are accumulated in the sensor portion 1, there is a fear that the vertical charge transfer portion 2 may become unable to transfer all the signal charges accumulated therein, and so called the left-off charges may be produced causing the deterioration of the transfer efficiency.

In the present embodiment, taking note of the fact that the handling charge quantity in the vertical charge transfer portion 2 depends on the magnitude of the charge accumulation area in the transfer direction, or in the vertical direction, and further the magnitude of the charge accumulation area in the transfer direction depends on the number of systems of the transfer electrodes under which deep potential wells are formed, a driving method as explained in the following is adopted.

When the case where signal charges for one line are transferred in the vertical direction in eight sectional periods (from t1 through t8) using the vertical driving pulses φV1, φV2, φV3 and φV4 of 4-phase is cited as an example, among these sectional periods from t1 through t8, periods t2, t4, t6 and t8 in which the number of systems of transfer electrodes applied with vertical driving pulses of a high level becomes minimum becomes two.

When the vertical charge transfer portion 2 is driven, the sectional periods in which the vertical driving pulses become a high level and the number of systems of transfer electrodes becomes minimum are set longer than the others. To be concrete, as shown in the timing chart in FIG. 5, the sectional periods t2, t4, t6 and t8 in which the number of systems of transfer electrodes applied with vertical driving pulses of a high level becomes two are set longer than the sectional periods t1, t3, t5 and t7 in which the number of systems of transfer electrodes applied with high level driving pulses becomes three. Provided that the transfer time T, the total of eight sectional periods, is set to be the same as that in the timing chart shown in FIG. 2. In short, in comparison with the timing chart shown in FIG. 2, corresponding to the extended period of time for each sectional period of t2, t4, t6 and t8, the time for each sectional period of t1, t3, t5 and t7 is shortened.

As mentioned in the above, the sectional periods t2, t4, t6 and t8, in which the number of systems of the transfer electrodes to be applied with vertical driving pulses in a high level becomes minimum are set longer than the other sectional periods t1, t3, t5 and t7, therefore, in the sectional periods t2, t4, t6 and t8, a larger charge accumulation area in the transfer direction can be secured than that in other sectional periods.

In the sectional periods t1, t3, t5 and t7, the number of systems of transfer electrodes to be applied with vertical driving pulses in a high level becomes three, so that in consideration of the balance with the number of systems, these sectional periods are shortened in order that the magnitude of the charge accumulation area in the transfer direction is not smaller than that in the periods t2, t4, t6 and t8, which makes it possible to avoid the influence on the handling charge quantity in the vertical charge transfer portion 2.

Owing to the arrangement explained in the above, it is made possible to increase the handling charge quantity in the vertical charge transfer portion 2 without changing the total transfer time of eight sectional periods in a vertical transfer period, so that, for example, to respond to the correction of blur caused by an unintentional hand move, even if signal charges are transferred at a high speed in the vertical charge transfer portion 2, it is possible to control the decrease in the handling charge quantity to the utmost.

The verification of the degree of improvement in comparing two kinds of timings were carried out by actually driving the transfer electrodes in the vertical charge transfer portion 2 using the same CCD solid-state image sensing device with the driving timing shown in FIG. 2 and the driving timing shown in FIG. 5, and the results obtained are shown in FIG. 6.

In FIG. 6, the results corresponding to the driving timing shown in FIG. 2 are shown with black circles and those corresponding to that shown in FIG. 5 are shown with white circles. About the transfer speed (Vφ speed), the extended period of time in sectional periods, t2, t4, t6 and t8 is denoted by 1-bit and the transfer time per sectional period is expressed on bit basis. It means that, for example, at the position denoted by a downward arrow indicates that 4 bits are transferred per sectional period, while in the sectional periods t2, t4, t6 and t8, the transfer time is prolonged by 1-bit.

It will be understood easily from this figure that the effect of the invention begins to appear gradually at a point where the handling charge quantity starts to decrease, and the degree of effectiveness becomes larger with the growth of the transfer speed. 

1. A driving method for a solid-state image sensing device having a plurality of sensor portions arranged two-dimensionally in horizontal and vertical directions, and a vertical charge transfer portion adjacent said plurality of sensor portions provided with transfer electrodes comprising the steps of: selectively applying high level driving pulses to groups of said transfer electrodes in a vertical transfer period; and transferring signal charges read out from said plurality of sensor portions in the vertical direction; wherein a period during a vertical transfer operation in which the number of groups of transfer electrodes receiving high level driving pulses becomes minimum is longer than that of other periods, wherein individual groups of transfer electrodes are correspondingly associated with four systems and the vertical transfer period is divided into eight from periods t1 through t8, wherein periods t2, t4, t6 and t8, in which the number of groups of said transfer electrodes receiving high level driving pulses is two, are longer than the periods t1, t3, t5 and t7, in which the number of groups of said transfer electrodes receiving said high level driving pulses becomes three.
 2. A driving method for a charge transfer device having a charge transfer portion and transfer electrodes of a plurality of different groups disposed in the charge transfer direction, comprising the steps of: selectively applying a high level driving pulse to said transfer electrodes in a transfer period; and transferring signal charges in a charge transfer portion; wherein a period during a charge transfer operation in which the number of groups of said transfer electrodes receiving high level driving pulses becomes minimum is longer than other periods, wherein the groups of transfer electrodes are correspondingly associated with four systems and the vertical transfer operation is divided into eight periods from t1 through t8, wherein the periods t2, t4, t6 and t8, in which the number of groups of said transfer electrodes receiving high level driving pulses is two, are longer than the periods t1, t3, t5 and t7, in which the number of groups of said transfer electrodes receiving high level driving pulses is three. 